Electrochemical cell comprising channel-type flowable electrode units

The invention claimed is: 1. A channel-type flow-electrode structure comprising at least two channel-type flow-electrode units; wherein the two adjacent channel-type flow-electrode units share an integral liquid-permeable wall; wherein a basic frame comprising a plurality of channels, in which a fluid is introduced from an inlet and discharged to an outlet, is formed by said liquid-permeable wall and then some or all of the channels confined by the liquid-permeable wall constitute the flow-electrode unit; and wherein said channel-type flow-electrode unit comprises: a channel-type liquid-permeable wall confining a structure of the electrode unit as a scaffold; an ion-exchangeable current collector passing a positive ion or a negative ion and having electrical conductivity, which is placed on an inner surface of the liquid-permeable wall; and an electrode flow channel separated from the liquid-permeable wall by the ion-exchangeable current collector, along an inside of which an electrode active material-containing fluid introduced from a channel inlet and discharged to a channel outlet flows. 2. A channel-type flow-electrode unit structure comprising at least two channel-type flow-electrode units; wherein the two adjacent channel-type flow-electrode units share an integral liquid-permeable wall; wherein a basic frame comprising a plurality of channels, in which a fluid is introduced from an inlet and discharged to an outlet, is formed by said liquid-permeable wall and then some or all of the channels confined by the liquid-permeable wall constitute the flow-electrode unit; and wherein said channel-type flow-electrode unit comprises: a channel-type liquid-permeable wall confining a structure of the electrode unit as a scaffold; an ion-exchangeable material applied to an inner surface or an outer surface of the channel-type liquid-permeable wall, the liquid-permeable wall itself, or a combined position thereof to allow a positive ion or a negative ion to pass therethrough; a porous current collector applied to an inner surface of the liquid-permeable wall to which the ion-exchange material has been applied; and an electrode flow channel separated from the liquid-permeable wall by the porous current collector, along an inside of which an electrode active material-containing fluid introduced from a channel inlet and discharged to a channel outlet flows. 3. The channel-type flow-electrode structure of claim 1 , wherein the ion-exchangeable current collector is formed by stacking an ion-exchangeable membrane and a porous current collector. 4. The channel-type flow-electrode structure of claim 1 , wherein the channel-type flow-electrode units are assembled in the form of a block. 5. The channel-type flow-electrode structure of claim 2 , wherein the channel-type flow-electrode units are assembled in the form of a block. 6. The channel-type flow-electrode structure of claim 1 , further comprising an electrolyte flow channel. 7. The channel-type flow-electrode structure of claim 2 , further comprising an electrolyte flow channel. 8. The channel-type flow-electrode structure of claim 1 , wherein an electrolyte is supplied through a separate channel-type flow channel for the electrolyte, a liquid-permeable wall, or through both; and with reference to the channel, the electrolyte is supplied in a longitudinal direction of the channel, a lateral direction of the channel, or in both directions. 9. The channel-type flow-electrode structure of claim 2 , wherein an electrolyte is supplied through a separate channel-type flow channel for the electrolyte, a liquid-permeable wall, or through both; and with reference to the channel, the electrolyte is supplied in a longitudinal direction of the channel, a lateral direction of the channel, or in both directions. 10. A cell equipped with a channel-type flow-electrode structure of claim 1 , comprising: a channel-type flow-cathode unit confined by a channel-type liquid-permeable wall, wherein a cathode ion-exchangeable current collector passing a positive ion and having electrical conductivity is placed on an inner surface of the channel-type liquid-permeable wall; a channel-type flow-anode unit confined by a channel-type liquid-permeable wall, wherein an anode ion-exchangeable current collector passing a negative ion and having electrical conductivity is placed on an inner surface of a channel-type liquid-permeable wall; and an electrode flow channel separated from the liquid-permeable wall by the ion-exchangeable current collector, along an inside of which an electrode active material-containing fluid introduced from a channel inlet and discharged to a channel outlet flows. 11. A cell equipped with a channel-type flow-electrode structure of claim 2 , comprising: a channel-type flow-cathode unit confined by a channel-type liquid-permeable wall, wherein an ion-exchangeable material is applied to an inner surface or an outer surface of the channel-type liquid-permeable wall, the liquid-permeable wall itself, or a combined position thereof to allow a positive ion to pass therethrough and then a porous current collector is applied to an inner surface of the liquid-permeable wall to which the ion-exchangeable material has been applied; a channel-type flow-anode unit confined by a channel-type liquid-permeable wall, wherein an ion-exchangeable material is applied to an inner surface or an outer surface of a channel-type channel-type wall, a channel-type wall itself, or a combined position thereof to allow a negative ion to pass therethrough and then a porous current collector is applied to an inner surface of the channel-type wall to which the ion-exchangeable material has been applied; and an electrode flow channel separated from the liquid-permeable wall by the ion-exchangeable current collector, along an inside of which an electrode active material-containing fluid introduced from a channel inlet and discharged to a channel outlet flows. 12. A channel-type flow-electrode structure, comprising: an ion-exchangeable membrane scaffold which forms a basic frame for a plurality of channels, in which a fluid is introduced from an inlet and discharged to an outlet; the channel-type flow-cathode unit of claim 2 , comprising: a porous cathode plate arranged on an inner surface of channel(s) confined by the ion-exchangeable membrane scaffold, and a cathode flow channel separated from the channel-type ion-exchangeable membrane scaffold by the porous cathode plate, along an inside of which a cathode active material-containing fluid introduced from a channel inlet and discharged to a channel outlet flows; and the channel-type flow-anode unit of claim 2 , comprising: a porous anode plate arranged on an inner surface of other channel(s) confined by the ion-exchangeable membrane scaffold, and an anode flow channel separated from the channel-type ion-exchangeable membrane scaffold by the porous anode plate, along an inside of which an anode active material-containing fluid introduced from a channel inlet and discharged to a channel outlet flows. 13. A capacitive flow-electrode device comprising the channel-type flow-electrode structure of claim 12 . 14. A redox flow battery device comprising the channel-type flow-electrode structure of claim 12 .